Figures
Abstract
Objectives
To compare the dopaminergic neuronal imaging features of different subtypes of genetic Parkinson's Disease.
Methods
A retrospective study of genetic Parkinson's diseases cases in which DaTSCAN (123I-FP-CIT) had been performed. Specific non-displaceable binding was calculated for bilateral caudate and putamen for each case. The right:left asymmetry index and striatal asymmetry index was calculated.
Results
Scans were available from 37 cases of monogenetic Parkinson's disease (7 glucocerebrosidase (GBA) mutations, 8 alpha-synuclein, 3 LRRK2, 7 PINK1, 12 Parkin). The asymmetry of radioligand uptake for Parkinson's disease with GBA or LRRK2 mutations was greater than that for Parkinson's disease with alpha synuclein, PINK1 or Parkin mutations.
Citation: McNeill A, Wu R-M, Tzen K-Y, Aguiar PC, Arbelo JM, Barone P, et al. (2013) Dopaminergic Neuronal Imaging in Genetic Parkinson's Disease: Insights into Pathogenesis. PLoS ONE 8(7): e69190. https://doi.org/10.1371/journal.pone.0069190
Editor: Wolfdieter Springer, Mayo Clinic, United States of America
Received: April 2, 2013; Accepted: June 5, 2013; Published: July 23, 2013
Copyright: © 2013 McNeill et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This work was supported in part by the Wellcome Trust/MRC Joint Call in Neurodegeneration award (WT089698) to the UK Parkinson's Disease Consortium (UKPDC) whose members are from the UCL/Institute of Neurology, the University of Sheffield and the MRC Protein Phosphorylation Unit at the University of Dundee. AM was supported by a United Kingdom Medical Research Council Research Training Fellowship and Centenary Award (G1001983). AHVS is supported by the Wellcome Trust, Parkinson’s Disease UK and the Kattan Trust. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: Below are the authors' declarations of funding sources, including commercial funders: Rueey-Mei Wu - Analysis of data, revising manuscript. Government research support National Science Council (96-2628-B-002-102-MY3), academic research support not attributed in manuscript National Science Council (98-2628-B-002-072-MY3) National Taiwan University Hospital (100-S1636), on editorial boards Parkinsonism and related disorders, Journal of Formosan Medical Association, Acta Neurologica Taiwanica and no conflicts of interest. Patricia Aguiar - Analysis and interpretation of data. Funding for travel from Roche, government research support FAPESP (grants 2010/19206-0; 2011/18202-3; 2011/14116-5, research grant from Edmond J Safra foundation and no conflicts of interest. Rodrigo Bressan - Analysis and interpretation of data. Research funding from Janssen, Eli Lily, Lundbeck, Novartis, Roche, FAPESP, CNPq, CAPES, Fundação Safra, Fundação ABADS. Shareholder in Radiopharmacus Ltda, Biomolecular Technology Ltda. Speaking fees from Astra Zeneca, Bristol, Janssen, Lundbeck, Roche. No conflicts of interest. Andre Felicio - Analysis and interpretation of data. funding for travel from Roche, Honoraria from Gerson Lehrman group, research funding from Parkinson's society Canada and no conflicts of interest. Henrique Ferraz - Analysis and interpretation of data. Funding for travel from Roche and Novartis and no conflicts of interest. Andrew Lees -Andrew Lees discloses financial support from the Reta Lila Weston Trust, University College London, Parkinson's UK and PSP Association. He is on the specialist board for Novartis, Teva, Meda, Boehringer Ingelheim, GSK, Ipsen, Lundbeck, Allergan, Orion, BIAL, Noscira, Roche, has received consultancy fees from Genus, and honoraria from Novartis, Teva, Meda, Boehringer Ingelheim, GSK, Ipsen, Lundbeck, Allergan, Orion, BIAL, Noscira and Roche. Laura Silveria-Moriyama - Analysis and interpretation of data. Laura Silveira-Moriyama discloses financial support from the Reta Lila Weston Trust, University College London, University of Campinas, Parkinson's UK and Virginia Keiley Benefaction, and travels grants from UCB, Teva and Boehringer-Ingelheim. Tom Foltynie - Analysis and interpretation of data. Honoraria for speaking at meetings sponsored by St Jude medical, Abbott, Novartis. Grant support from Parkinson's UK, Cure Parkinson's Trust, the European Union and the Brain Research Trust. Anthony HV Schapira - Study design, analysis and interpretation of data, revising manuscript. Receives funding from the United Kingdom Medical Research Council, Wellcome Trust, Parkinson's UK and Kattan Trust. Specialist boards and educational symposia for Orion-Novartis, Teva-Lundbeck, Merck, BI, UCB. AH Schapira is an NIHR Senior Investigator. This does not alter the authors' adherence to all the PLOS ONE policies on sharing data and materials.
Introduction
Parkinson's disease (PD) is the second most common neurodegenerative disorder worldwide with a prevalence of 1–2% in the population aged over 65 years [1]. The vast majority of PD is late onset, sporadic and of unknown aetiology. However, 5–10% of PD cases are associated with mutations in a range of genes inherited in an autosomal dominant, autosomal recessive or apparently sporadic pattern [2]. The most common genetic risk factor for PD is mutation of the glucocerebrosidase (GBA) gene, which encodes a lysosomal enzyme deficient in the lysosomal storage disorder Gaucher disease (GD) [1]. In sporadic PD between 5–30% of cases have a heterozygous GBA mutation, with the highest frequency in Ashkenazi Jews, while 8.4% of European autosomal dominant PD families have GBA mutations [3]. The second most common genetic cause of PD is the G2019S mutation of LRRK2, which typically presents with late onset features resembling sporadic PD [4]. The frequency of LRRK2 G2019S in sporadic PD in Caucasians varies from 0.5–5% depending on population studied [1], [4]. Mutations of the SNCA gene, which encodes alpha synuclein, the principle component of the Lewy body, cause early onset autosomal dominant PD [5]. SNCA mutations are rare, accounting for less than 0.5% of PD cases [1], [5]. The penetrance for development of PD varies greatly between these different genes; being 15% by age 80 for GBA [12], around 80% by age 80 for LRRK2 [4] and almost 100% for SNCA mutations [1], [5]. This suggests that mutations in GBA or LRRK2 are not sufficient by themselves to cause symptomatic PDneurodegeneration and that interactions between GBA or LRRK2 protein and other genetic or environmental factors influence penetrance.
Autosomal recessive Juvenile Parkinson's disease (ARJPD) is clinically distinct from both sporadic PD and the genetic causes outlined above [6]. Fifty percent of familial and 15% of sporadic early onset PD (onset before 45 years old) is due to bi-allelic mutations (i.e. homozygous or compound heterozygous) in the Parkin gene [1], [6]. Parkin disease differs from non-Parkin PD in that early lower limb dystonia and bilateral motor Parkinsonian signs are more common, non-motor symptoms are less severe and, in general, there is an absence of Lewy bodies histologically [6], [7], [8]. PINK1 mutations are the second most common cause of early onset PD, present in 2–4% of cases [9]. Clinical reports of PINK1 associated PD emphasise a slow disease progression, prominent gait impairment and marked neuropsychiatric symptoms compared to sporadic PD [9]. Mutations in DJ-1 are rare, accounting for just 1% of early onset PD [1], [6]. Bi-allelic mutations in PINK1, Parkin and DJ-1 are highly penetrant for PD, suggesting that interactions with additional genetic or environmental factors are not required for neurodegeneration to occur in these genetic subtypes of PD.
PD is diagnosed clinically based upon the Queens Square Brain Bank criteria, with a positive predictive value of 90% for neuropathological evidence of PD if these criteria are met [1]. In clinical practice imaging to detect pre-synaptic dopaminergic neuronal dysfunction is performed to aid diagnosis when Parkinsonian signs are present but clinical criteria for PD are not fully met [10]. These imaging studies involve visualisation of radioactive dopamine transporter (DAT) ligands (e.g. 123-I-FP-CIT, 99m-Tc-TRODAT-1) or 18F-DOPA with positron emission tomography (PET) or single photon emission computed tomography (DAT-SPECT). DAT-SPECT and 18F-DOPA-PET have been studied extensively in sporadic PD and “Parkinson's plus” syndromes [10]. However, there are limited reports of dopaminergic neuronal imaging in genetic PD. We sought to examine the hypothesis that mutations in GBA and LRRK2 would have asymmetrical loss of radioligand, reflecting initially focal neurodegeneration due to interactions with additional endogenous or exogenous pathogenic factors, whilst PD with bi-allelic PINK1 or Parkin mutations would manifest more symmetrical radioligand loss since mutations in these genes alone is sufficient to induce neurodegeneration. To do this, we studied 123-I-FP-CIT (DaTSCAN) appearances in what is to our knowledge the largest series of genetic PD patients reported.
Materials and Methods
We formed a consortium of Movement Disorders and Neurogenetics centres from Western Europe, South America and Asia to identify a large series of monogenetic PD cases. Mutations in GBA, SNCA, LRRK2, Parkin, or PINK1 were identified by molecular genetic sequencing according to standard clinical protocols. From amongst such patients individuals who had been imaged with DaTSCAN as part of their initial clinical evaluation were identified by retrospective chart review. Electronic copies of each scan were collated for analysis at a single site (University College London).
A region of interest (ROI) analysis was performed using Image J (NIH, Bethesda, MD). Four ROIs were anatomically defined: right and left caudate, right and left putamen. ROIs were manually defined using the ellipse tool in Image J. To permit calculation of background signal a region of occipital cortex was designated as a 5th ROI. The outcome measure was the specific-to-nondisplaceable binding ratio V3” (ROIstriatum – ROIoccipital/ROIoccipital) [11]. For each ROI, 4 transaxial slices were analysed. Four slices showing the most intense radiotracer uptake were selected for analysis from each case. For each case the right:left asymmetry index (ASI, most severely affected ROI V3”/least severely affected ROI V3”, e.g. ipsilateral caudate ROI V3”/contralateral caudate ROI V3”) was calculated for caudate and putamen [11]. The whole striatal asymmetry index was also calculated (SASI: (ipsilateral-contralateral striatum V3”)/((ipsilateral+contralateral striatumV3”)/2)*100%), where the striatum was defined as the caudate plus putamen value [9]. The ASI calculates the ratio of ligand binding in the most severely affected caudate or putamen compared to the least severely affected side, a ratio of 1.0 indicates perfect symmetry while values of less than 1.0 indicate progressively worse asymmetry. This score enables differentiation of whether asymmetry is predominantly due to loss of caudate or putamen uptake. The SASI gives a summary measure of asymmetry in the whole striatum, defined as uptake in caudate plus putamen. Higher SASI values indicate greater degrees of asymmetry. Images were analysed blind to the genetic diagnosis by a single investigator (AM), apart from the SNCA scans which were reported by SB.
Statistical analysis was performed with PASW 20.1 (version 20.1, IBM). Differences in median ASI and SASI between genotypes were sought using the Mann-Whitney U-test. Significance was taken at the 5% level (p = 0.05), with bonferroni correction (i.e. p = 0.05/n where n = number of comparisons). Demographic variables of patients were compared using one way ANOVA and chi-squared test.
Ethics Statement
All participating institutions had research ethics board approvals for the project and written informed consent was taken as appropriate. No participant had cognitive impairment which meant they could not give informed consent. London: North West London Research Ethics Committee (REC number 10/H0720/21). Spain: The Institutional Review Board (IRB) at the University of Navarra, (Pamplona, Spain) approved the study. Brazil: Ethics committee of Hospital Israelita Albert Einstein Taiwan: Research Ethics committee C. Taiwan: National Taiwan University Hospital. Italy: ethics committee of University of Naples Federico II. Rotterdam: medical ethics committee of Erasmus MC Rotterdam.
Results
Clinical and genetic characteristics of the 37 genetic PD patients enrolled are given in Table 1. Table 2 summarises DaTSCAN findings. Control DaTSCAN images were available from 12 individuals without neurological disease from the European Nuclear Medicine Consortium (provided by Dr John Dickson, Nuclear Medicine Department University College London Hospital). All scans were performed according to standard clinical protocols. All of the DaTSCANS utilised in the current study had previously been reported as showing reduction of radioligand binding compatible with PD. Ethical approvals were obtained at each centre and written informed consent taken as required. The PINK1 [9], heterozygous GBA mutation associated PD [12], Brazilian Parkin and LRRK2 patients [13], SNCA cases [14] and Italian Parkin cases [15] have been reported previously.
The age at assessment (one way ANOVA, p>0,05), sex and proportion of patients taking levo-dopa for each genetic subgroup did not differ significantly (both chi-squared test, p>0.05) (Table 1). The disease duration did not differ between groups (one way ANOVA, F = 2.3, p = 0.076). The UPDRS part III scores for the PINK1 group were significantly lower than the other genetic subgroups (p<0.05 for all comparisons with Bonferroni correction). The control group were all of Western European ancestry but did not differ significantly from the PD group for age (52+/−12 years, p>0.05) or sex (7/12 male, chi-squared test p>0.05).
The caudate ASI for the PD cases with GBA mutations (Mann-Whitney U-test, median ASI 0.42 [0.33–0.56], p<0.001) was different to the control value of 0.92 (interquartile range 0.89–0.92) (Table 1 and Figure 1a). The caudate asymmetry indices for PD with bi-allelic Parkin (median 0.88 [0.72–0.93]. p = 0.19), PINK-1 (median 1.0 [0.9–1.13], p = 0.065), LRRK2 G2019S (median 1.0 [0.6–1.1], p = 0.38), or SNCA (median 1.02 [0.9–1.13], p = 0.91) did not differ from the control value. This indicates an asymmetric reduction of radioligand uptake in the caudate of PD associated with GBA mutations with a relatively symmetrical reduction in ligand uptake in the caudate of PINK1, Parkin, LRRK2 G2019S and SNCA mutation associated PD.
1a. Boxplot of caudate asymmetry index for each genotype. Median caudate asymmetry is signficantly different for GBA compared to control. 1b. Boxplot of putamen asymmetry index for each genotype. Median putamen asymmetry is significantly different for GBA and LRRK2 groups compared to control.
The putamen ASI for PD cases with GBA mutations (median 0.18 [0.08–0.33], p<0.001) and LRRK2 (median 0.52 [0.13–0.5], p<0.001) differed significantly from the control value (median 0.89 [0.82–0.96])(Figure 1b). The putamen ASI for bi-allelic Parkin (median 0.69 [0.2–1.0], p = 0.2), PINK1 (median 1.05 [0.9–1.4], p = 0.14) and SNCA (median 1.05 [0.92–1.22], p = 0.30) mutation associated PD did not differ from control values (median 0.89 [0.82–0.86]). This indicates an asymmetric reduction of radioligand uptake in the putamen of PD associated with GBA and LRRK2 mutations with a relatively symmetrical reduction in ligand uptake in the putamen of PINK1, Parkin and SNCA mutation associated PD.
To further explore these findings, the whole striatum asymmetry index (SASI) was calculated (Figure 2). Mann-Whitney U testing with bonferroni correction demonstrated that the SASI for PD-GBA (mean 80.5+/−5.1, p = 0.001) and LRRK2 (44.0+/−11.5, p = 0.009) was significantly higher than controls (mean 8.3+/−2.7). The SASI did not differ significantly between PINK1, Parkin, SNCA and controls (p>0.05 for all). Representative DaTSCANS are shown in Figure 3.
The striatal asymmetry index was significantly higher for the GBA and LRRK2 genotypes (p<0.001). Graph shows mean SASI +/−1 standard error.
3a. DaTscan from 50 year old man with GBA mutation, note predominantly right sided tracer loss. 3b. DaTscan from 67 year old woman with PINK1 mutation associated Parkinson's disease, note symmetrical loss of tracer uptake in caudate heads. 3c. DaTscan from 45 year old man with Parkin mutation associated Parkinson's disease and symmetrical loss of tracer uptake. 3d. DaTscan from 32 year old man with LRRK2 mutation, note asymmetrical loss of tracer uptake in caudate heads.
Discussion
Here we report what is, to our knowledge, the largest series directly comparing the dopaminergic imaging features of the most important causes of genetic PD. The key finding is a difference in the pattern of imaging abnormality between the separate mutations. GBA and LRRK2 mutations are associated with relatively asymmetric striatal dopaminergic neuronal loss, while Parkin, PINK1 and SNCA mutation patients have relatively symmetrical loss. We believe that this difference in the pattern of striatal dopaminergic loss reflects separate influences of the respective mutations on the aetiopathogenesis of PD.
The results of our comparison of dopaminergic neuronal imaging features are in keeping with previous reports of imaging of single PD genotypes. There are 2 reports of DAT-SPECT in Gaucher disease patients with PD or PD patients with heterozygous GBA mutations [16], [17]. Though not formally quantified, inspection of the published images reveals clear asymmetry of radioligand uptake affecting the striatum. Here we confirm asymmetric loss of dopaminergic neurons in PD associated with heterozygous GBA mutations.
Multiple studies of Parkin mutation associated PD using both DAT-SPECT and 18-F-DOPA-PET clearly describe a symmetrical reduction in striatal radioligand uptake [18]–[20]. The DAT-SPECT and 18-F-DOPA-PET features of PD patients with bi-allelic Parkin mutations reported herein is entirely in keeping with this. DAT-SPECT in PINK1 linked PD is usually described as symmetrical but some reports state that it is asymmetrical in a pattern reminiscent of sporadic PD [9], [21]–[22]. As previously described we found that the LRRK2 mutation carriers with PD had relatively asymmetric loss of radioligand uptake on DAT-SPECT [23], [24]. The SNCA mutation PD cases reported here had symmetric reduction of ligand binding. This is in keeping with reports of 18F-DOPA in PD with the A53T mutation which demonstrated relatively symmetrical loss of radioligand uptake [25], however, reports of SNCA multiplication associated PD describe an asymmetrical pattern of reduced tracer uptake [26], [27].
The currently available data on the pathogenetic mechanisms underlying monogenetic PD may help to explain the differences in symmetry of radioligand uptake between genotypes [28], [29]. Intuitively, it might be expected that a genetic cause of PD present from birth and presumably expressed symmetrically in expressing tissues, would result in symmetric clinical features and striatal imaging loss. In agreement with this PINK1 and Parkin mutations are generally associated with early onset, relatively symmetrical parkinsonism [1], [6]. Both PINK1 and Parkin proteins are proposed to play a role in clearing damaged mitochondria, and there is evidence that loss of function of these proteins is associated with mitochondrial dysfunction [30], [31]. The diffuse and symmetrical loss of dopaminergic neurons reported by us, and others [18], [20]–[22], may reflect widespread dysfunction and degeneration of striatal dopaminergic neurons due to a general predisposition to neuronal mitochondrial dysfunction in PINK1 and Parkin mutation associated PD. SNCA mutations are proposed to act chiefly by facilitating Lewy body formation [32]. The symmetrical loss of dopaminergic neurons on DAT-SPECT reported herein may thus reflect a generalised, homogeneous increase in Lewy body formation in the striatum since the mutation is present in every cell.
By contrast, GBA and LRRK2 mutations are most commonly associated with a phenotype and age of onset that closely resembles late onset sporadic PD [1], [4], [12]. This suggests that these mutant proteins may interact with additional pathogenetic process, either genetic or environmental, predisposing to age related PD. For example in PD with mono- or bi-allelic GBA mutations there is reduction or loss of glucocerebrosidase enzyme activity in the brain, most severe in the substantia nigra [35], associated with elevated alpha-synuclein deposition as measured by Western blot [35]. Both cell biology and mouse studies indicate that inhibition of glucocerebrosidase activity is associated with elevated alpha-synuclein accumulation [33]. The asymmetric loss of dopaminergic neurons observed in PD with GBA mutations may thus reflect a stochastic element whereby there is a focal loss of glucocerebrosidase activity below a critical level eventually resulting in an initially focal accumulation of alpha-synuclein and Lewy body formation. There is evidence from human brain and cell models that alpha-synuclein accumulation results in inhibition of glucocerebrosidase, thus causing a “feed forward” mechanism which could contribute to the spread of pathology and neurodegeneration [33], [34]. We recently described loss of glucocerebrosidase activity associated with alpha-synuclein accumulation in brain tissue from PD without GBA mutations [33]. This suggests that a similar mechanism may operate in sporadic PD and may account partly for the similarities in dopaminergic neuronal imaging and clinical phenotype between sporadic PD and PD associated with GBA mutations. We hypothesised that GBA mutations accelerated or enhanced pathogenetic mechanisms associated with the cause of sporadic PD [33] and the present imaging results support this. Mutant LRRK2 protein has recently been shown to inhibit chaperone mediated autophagy. In theory this could result in focal loss of lysosomal degradation of alpha-synuclein in the brain of LRRK2 G2019S mutation carriers, causing initially asymmetrical Lewy body deposition and loss of dopaminergic neurons [35].
Recessive forms of genetic PD (Parkin, PINK1) generally demonstrate relatively symmetric loss of radioligand uptake in the striatum. PD associated with heterozygous mutations in GBA or LRRK2 G2019S, which can present with dominant or apparently sporadic PD, produces a relatively asymmetric pattern of loss of radioligand uptake. In clinical practice asymmetric loss of radioligand binding should not exclude a genetic aetiology for PD while relatively symmetric decrease should raise suspicion of a monogenetic form of PD. The asymmetric loss of dopaminergic neurons in GBA and LRRK2 associated PD supports the hypothesis of additional interactions with genetic or environmental factors leading to age related neurodegeneration in these genotypes.
Author Contributions
Conceived and designed the experiments: AM AHVS. Performed the experiments: AM SB. Analyzed the data: AM SB. Contributed reagents/materials/analysis tools: AM RMW KYT PCA JMA PB KB OB VB SB RB GC PC AF HBF JH HH MH CI AL OLB NEM PP SP MTP LSM AV TF AHVS. Wrote the paper: AM AHVS.
References
- 1. Lees AJ, Hardy J, Resvez T (2009) Parkinson's disease. Lancet 373: 2055–2066.
- 2. Schapira AH, Jenner P (2011) Etiology and pathogenesis of Parkinson's disease. Mov Disord 26: 1049–1055.
- 3. Lesage S, Anheim M, Condroyer C, Pollak P, Durif F, et al. (2011) Large scale screening of the Gaucher's disease related glucocerebrosidas gene in Europeans with Parkinson's disease. Hum Mol Genet 20: 202–10.
- 4. Healy DG, Falchi M, O'Sullivan SS, Bonifati V, Durr A, et al. (2008) Phenotype, genotype and worldwide penetrance of LRRK2 -associated Parkinson's disease. Lancet Neurol 7: 583–590.
- 5. Warner TT, Schapira A (1998) The role of the alpha-synuclein gene mutation in patients with sporadic Parkinson's disease in the United Kingdom. J Neurol Neurosurg Psych 65: 378–379.
- 6. Kitada T, Tomlinson JJ, Ao HS, Grimes DA, Schlossmacher MG (2012) Considerations regarding the etiology and future treatment of autosomal recessive versus idiopathic Parkinson's disease. Curr Treat Options Neurol 14: 230–240.
- 7. Kägi G, Klein C, Wood NW, Schneider SA, Pramstaller PP, et al. (2010) Non-motor symptoms in Parkin gene related parkinsonism. Mov Disord 25: 1279–84.
- 8. Farrer M, Chan P, Chen R, Tan L, Lincoln S, et al. (2001) Lewy bodies and parkinsonism in families with Parkin mutations. Ann Neurol 50: 293–300.
- 9. Samaranch L, Lorenzo-Betancor O, Arbelo J, Ferrer I, Lorenzo E, et al. (2010) PINK1-linked parkinsonism is associated with lewy body pathology. Brain 133: 1128–1142.
- 10.
Bohnen NI, Minoshima S (2012) FDG-PET and molecular brain imaging in the movement disorders clinic. Neurology: epub August 22.
- 11. Plotkin M, Amthauer H, Klaffke S, Kühn A, Lüdemann L, et al. (2005) Combined 123-I-FP-CIT and 123I-IBZM SPECT for the diagnosis of parkinsonian syndromes: study on 72 patients. J Neural Trans 112: 677–692.
- 12. McNeill A, Duran R, Mehta A, Hughes D, Schapira AH (2012) A clinical and family history study of Parkinson's disease in heterozygous glucocerebrosidase mutation carriers. J Neurol Neurosurg Psych 83: 853–4.
- 13. Barsottini OG, Felício AC, Aguiar P de C, Godeiro-Junior C, Shih MC, et al. (2009) Clinical and molecular neuroimaging characteristics of Brazilian patients with Parkinson's disease and mutations in PARK2 or PARK8 genes. Arq Neuropsiquiatr 67: 7–11.
- 14. Bostantjopoulou S, Katsarou Z, Gerasimou G, Costa DC, Gotzamani-Psarrakou A (2008) (123)I-FP-CIT SPET striatal uptake in parkinsonian patients with the alpha-synuclein (G209A) mutation. Hell J Nucl Med 11: 157–9.
- 15. Varrone A, Pellecchia MT, Amboni M, Sansone V, Salvatore E, et al. (2004) Imaging of dopaminergic dysfunction with [123-I]FP-CIT SPECT in early-onset Parkin disease. Neurology 63: 2097–2103Lin CH, Tzen KY, Tai CH, Tai CH, Farrer MJ et al. LRRK2 mutation in familial Parkinson’s disease in a Taiwanese population: clinical, PET, and functional studies. J Biomed Sci 2008 15: 661–667.
- 16. Sunwoo MK, Kim SM, Lee S, Lee PH (2011) Parkinsonism associated with glucocerebrosidase mutation. J Clin Neurol 7: 99–101.
- 17. Kono S, Shirakawa K, Ouchi Y, Sakamoto M, Ida H, et al. (2007) Dopaminergic neuronal dysfunction associated with parkinsonism in both a Gaucher disease patient and a carrier. J Neurol Sci 252: 181–184.
- 18. Ribeiro MJ, Thobois S, Lohmann E, du Montcel ST, Lesage S, et al. (2009) A multitracer dopaminergic PET study of young-onset parkinsonian patients with and without parkin gene mutations. J Nuc Med 50: 1244–1250.
- 19. Khan NL, Brooks DJ, Pavese N, Sweeney MG, Wood NW, et al. (2002) Progression of nigrostriatal dysfunction in a parkin kindred: an 18F-DOPA-PET and clinical study. Brain 125: 2248–2256.
- 20. Pavese N, Khan NL, Scherfler C, Cohen L, Brooks DJ, et al. (2009) Nigrostriatal dysfunction in homozygous and heterozygous parkin gene carriers: an 18F-dopa PET progression study. Mov Disord 24: 2260–2266.
- 21.
Weng YH, Chou YH, Wu WS, Lin KJ, Chang HC et al. (2007) PINK1 mutation in Taiwanese early-onset Parkinsonism: clinical, genetics, and dopamine transporter studies. J Neurol 1347–1355.
- 22. Kessler KR, Hamscho N, Morales B, Menzel C, Barrero F, et al. (2005) Dopaminergic function in a family with the PARK6 form of autosomal recessive parkinson's syndrome. J Neural Transm 112: 1345–1353.
- 23. Adams JR, van Netten H, Schulzer M, Mak E, Mckenzie J, et al. (2005) PET in LRRK2 mutations: comparison to sporadic Parkinson's disease and evidence for presymptomatic compensation. Brain 128: 2777–2785.
- 24. Isaias IU, Benti R, Goldwurm S, Zini M, Cilia R, et al. (2006) Striatal dopamine transporter binding in Parkinson's disease associated with the LRRK2 Gly2019Ser mutation. Mov Disord 21: 1144–1147.
- 25. Samii A, Markopoulou K, Wszolek ZK, Sossi V, Dobko T, et al. (1999) PET studies of parkinsonism associated with mutation in the alpha-synuclein gene. Neurology 53: 2097–2102.
- 26. Ahn TB, Kim SY, Park SS, Park SS, Lee DS, et al. (2008) Alpha-synuclein gene duplication is present in sporadic Parkinson disease. Neurology 70: 43–49.
- 27. Nishioka K, Ross OA, Ishii K, Kachergus JM, Ishiwata K, et al. (2009) Expanding the clinical phenotype of SNCA duplication carriers. Mov Disord 12: 1811–1819.
- 28. Schapira A, Tolosa E (2010) Molecular and clinical prodrome of Parkinson’s disease: implications for treatment. Nat Rev Neurol 6: 309–317.
- 29. Houlden H, Singleton AB (2012) The genetics and neuropathology of Parkinson’s disease. Acta Neuropathol 124: 325–38.
- 30. Gegg ME, Schapira AH (2011) PINK1-parkin-dependent mitophagy involves ubiquitination of mitofusins 1 and 2: Implications for Parkinson disease pathogenesis. Autophagy 7: 243–5.
- 31. Abramov AY, Gegg M, Grunewald A, Wood NW, Klein C, et al. (2011) Bioenergetic consequences of PINK1 mutations in Parkinson disease. PLoS One 6: e25622.
- 32. Ahmad B, Chen Y, Lapidus LJ (2012) Aggregation of alpha-synuclein is kinetically controlled by intramolecular diffusion. Proc Natl Acad Sci USA 109: 2336–2341.
- 33. Gegg ME, Burke D, Heales SJ, Cooper JM, Hardy J, et al. (2012) Glucocerebrosidase activity in substantia nigra of Parkinson's disease brains. Ann Neurol 72: 455–463.
- 34. Mazzulli JR, Xu YH, Sun Y, Knight AL, McLean PJ, et al. (2011) Gaucher disease glucocerebrosidase and alpha-synuclein form a bidirectional pathogenic loop in synucleinopathies. Cell 146: 37–52.
- 35. Orenstein SJ, Kuo SH, Tasset I, Arias E, Koga H, et al. (2013) Interplay of LRRK2 with chaperone-mediated autophagy. Nat Neurosci 16: 394–406.